A Direct Current (DC) motor is a rotating electrical device that converts direct current, of electrical energy, into mechanical energy. An Inductor (coil) inside the DC motor produces a magnetic field that creates rotary motion as DC voltage is applied to its terminal. Inside the motor is an iron shaft, wrapped in a coil of wire. This shaft contains two fixed, North and South, magnets on both sides which causes both a repulsive and attractive force, in turn, producing torque.
What is a DC Gear Motor?
A gear motor is an all-in-one combination of a motor and gearbox. The addition of a gear head to a motor reduces the speed while increasing the torque output. The most important parameters in regards to gear motors are speed (rpm), torque (lb-in) and efficiency (%). In order to select the most suitable gear motor for your application you must first compute the load, speed and torque requirements for your application.
Motor Selection Process
The motor selection process, at the conceptual design phase, can be challenging. The following key points can help you determine and select the most appropriate motor or gear motor for our application.
· Design Requirements – A design assessment phase where the product development requirements, design parameters, device functionality, and product optimization are studied.
· Design Calculations – Calculations used to determine which motor would be the best solution for your application. Design calculations determine gear ratio, torque, rotating mass, service factor, overhung load, and testing analysis.
· Types of DC Motors/Gearmotors – The most common electrical motors convert electrical energy to mechanical energy. These types of motors are powered by direct current (DC).
o Planetary Gear Motors
o Spur Gear Motors
o Coreless & Coreless Brushless
o Gear heads
· Motor Specifications – Once the design calculations are performed, and the application parameters are defined, you can use this data to determine which motor or gear motor will best fit your application. Some of the most common specs to consider when selecting a motor or gear motor would be:
o Life Expectancy / Duty Cycle
o Rotation (CW or CCW)
o Shaft Diameter and Length
o Enclosure Restrictions
Gear Motor Performance Curves
A motors performance and gearbox performance are combined into one graph by displaying three specific parameters. These three parameters are speed, torque and efficiency. These performance curves are essential when selecting a gear motor for your application.
Speed/Revolutions (N) – (unit: rpm) indicated as a straight line that shows the relationship between the gear motors torque and speed. This line will shift laterally depending on voltage increase or decrease.
Current (I) – (unit: A) indicated by a straight line, from no load to full motor lock. This shows the relationship between amperage and torque.
Torque (T) – (unit: gf-cm) this is the load borne by the motor shaft, represented on the X-axis.
Efficiency (η) – (unit: %) is calculated by the input and output values, represented by the dashed line. To maximize the gear motors potential it should be used near its peak efficiency.
Output (P) – (unit: W) is the amount of mechanical energy the gear motor puts out.
For example, let’s consider the performance curve below (figure 5) for a DC gear motor.
· Maximum operating efficiency (70%) for this motor would occur at 3.75 lb-in / 2,100 rpm.
· As torque increases the speed and efficiency decrease. The result of increased torque is poor output performance and the device will eventually fail to function once the motor reaches its stall torque (18 lb-in).
Gear motor performance curves are a helpful tool when selecting a motor for your application. To get the most out of the performance curves it’s important to thoroughly understand the applications requirements. You can use your load and speed requirements to help determine the required torque. Most DC motor and gear motor manufactures provide performance curves upon request.